This is called a downburst.
This phenomenon is called a derecho. It is a widespread and long-lived wind storm associated with a band of rapidly moving showers or thunderstorms. Derechos can cause significant damage over large areas due to the intense straight-line winds they produce.
Severe thunderstorms would probably be the answer. They can produce strong winds in more than one way. First, they can produce winds via a downburst which is a strong downdraft that occurs during a thunderstorm, and the causes strong, straight-line winds that can sometimes exceed 130 mph. In some cases downbursts can occur along a line of severe storms, resulting in a phenomenon called a derecho. Another way thunderstorms can produce strong winds is through a rear-flank downdraft or RFD, a descending mass of dry air associated with the mesocyclone, or rotating updraft, of a supercell. The RFD can produce winds in excess of 100 mph. It is also believed to play an essential role in tornado formation.
Spring tides are stronger than neap tides. Spring tides occur when the sun, moon, and Earth are aligned in a straight line, resulting in higher high tides and lower low tides. Neap tides occur when the sun and moon are at right angles to each other, resulting in less extreme tidal variations.
The kinetics of rectilinear translation focus on the forces and accelerations acting on an object moving in a straight line. This can involve analyzing the forces causing the motion, such as friction or external forces, and determining the resulting acceleration and velocity of the object. In essence, it deals with the relationships between forces, mass, and motion in a straight line.
All of their children will have straight hair, as the father can only pass on the dominant straight hair allele. The children will inherit one straight hair allele from their father and one curly hair allele from their mother, but the dominant straight hair allele will mask the recessive curly hair allele.
straight!
Yes, the resulting function is a straight line. This is the source:http://www.mathbench.umd.edu/mod207_scaling/page10.htm
To prove graphically that a reaction is first order, you would plot the natural log of the concentration of the reactant versus time. If the resulting graph is linear, then the reaction is first order. This linear relationship indicates that the rate of the reaction is directly proportional to the concentration of the reactant.
Severe thunderstorms would probably be the answer. They can produce strong winds in more than one way. First, they can produce winds via a downburst which is a strong downdraft that occurs during a thunderstorm, and the causes strong, straight-line winds that can sometimes exceed 130 mph. In some cases downbursts can occur along a line of severe storms, resulting in a phenomenon called a derecho. Another way thunderstorms can produce strong winds is through a rear-flank downdraft or RFD, a descending mass of dry air associated with the mesocyclone, or rotating updraft, of a supercell. The RFD can produce winds in excess of 100 mph. It is also believed to play an essential role in tornado formation.
The aft section of the ship pointed straight upright, then fell back again at an angle and planed under the surface. To the amazement of many in the lifeboats, it caused virtually no downdraft. It went down silently, with barely a whisper. The time was exactly 2:20 AM.
The order of a reaction can be determined graphically by analyzing concentration versus time data. For a first-order reaction, plotting ln(concentration) versus time should give a straight line. For a second-order reaction, plotting 1/concentration versus time should give a straight line. The slope of the line in these graphs reveals the order of the reaction.
There is no 'point on a graph' which represents Ohm's Law. It's the shape of the graph that determines whether Ohm's Law applies.If a graph is drawn showing the resulting variation in current for changes in voltage then, for Ohm's Law to apply, the graph must be a straight line.If the resulting graph is not a straight line, then Ohm's Law doesn't apply.
The straight answer appears to be no. The camps were known, the scale of the inhumanity was wholly unbelievable.
The rate order of a concentration of a substance using a graph depends on the constant k. For a reactant concentration versus time graph, k is minus and the order is zero. The same goes for a logarithm reactant concentration versus time graph where the order is one. But for an inverse of reactant concentration versus time graph, the order is two and k is positive. All these graphs should have straight lines and k is the value of the slope.
You do not need an associates degree to get a bachelors, one is just more extensive than the other. If I were you, I would go straight for the bachelors.
Straight tails are the wild type configuration. Straight tails are recessive and curly tails are dominant. So a Pig would have to be Cc (heterozyous) or cc (homozygous) for the strait tail characteristic to be passed on to it's offspring. The resulting offspring would only have the potential for straight tails if the other parent carried the recessive, straight tailed gene or was straight tailed.
Straight tails are the wild type configuration. Straight tails are recessive and curly tails are dominant. So a Pig would have to be Cc (heterozyous) or cc (homozygous) for the strait tail characteristic to be passed on to it's offspring. The resulting offspring would only have the potential for straight tails if the other parent carried the recessive, straight tailed gene or was straight tailed.
The result would be that all the offspring would have straight toes because the male contributes the recessive curled toes allele (ss) and the female can only contribute the dominant straight toes allele (S). Therefore, all the offspring would inherit one S allele from the female and an s allele from the male, resulting in the phenotype of straight toes (Ss).